NEWS & PRESS

Combining 26-year old data with supercomputer simulations, a team of scientists at Imperial College London have modelled Neptune’s magnetic field in detail for the first time. The researchers find that the furthest planet from the Sun has a badly behaved magnetic field, but one that may help us understand the risks from ‘space weather’ around Earth. Lars Mejnertsen, of Imperial College London, presented their findings in a presentation today (8 July) at the RAS National Astronomy Meeting at Venue Cymru, in Llandudno, Wales.

Neptune as observed by Voyager 2 during its flyby in 1989. Credit: NASA / JPL. Click for a full size imageNeptune, the outermost planet of the solar system, has only been visited by one spacecraft, Voyager 2, which zoomed past in 1989 and is now on its way to interstellar space. The Voyager 2 dataset was incredibly rich, but raised more questions than answers. One of the biggest puzzles is that Neptune’s rotation axis is tilted relative to the Sun, its magnetic axis is not at all aligned with its rotation and its magnetic field environment has a lopsided shape.

Team member Dr Adam Masters, a planetary scientist at Imperial, commented: “Imagine taking the Earth, tipping it over diagonally, and then moving its magnetic north pole to central Europe, and you start to get a sense of what Neptune is like. The planet’s unique magnetic field is still very poorly understood, and our new modelling represents a big leap forward.”

Understanding Neptune is important because it challenges our basic understanding of how the magnetic fields of planets and exoplanets can behave, and the lessons learned modelling Neptune can also be applied to understand how the Earth’s magnetic field affects space weather.

Although new missions to Neptune have been proposed, none are likely to arrive for many decades. So for now, the only way to better understand how the planet works is through computer simulations. In a new example of interdisciplinary research at Imperial College London, the space and atmospheric physics group and the plasma physics group have been working together to address this challenge.

Prof Jerry Chittenden of the plasma physics group worked with Dr Jonathan Eastwood, a lecturer in the space and atmospheric physics group, and PhD student Lars Mejnertsen. The scientists took simulations designed to understand plasma experiments in laboratories on Earth and applied them to space environments. Plasma, the gaseous ‘fourth state’ of matter consisting of electrically charged particles, is commonly found in space, albeit in highly rarefied amounts, and this causes planetary magnetic fields to form structures in space known as magnetospheres.

Modelling an entire planet needs a vast simulation, so the team turned to the Science and Technology Facilities Council’s DiRAC supercomputer. DiRAC’s ability to use hundreds or even thousands of processors in parallel was crucial to vastly speeding up the calculations.

The results show that Neptune’s magnetic field is constantly rotating and changing, and has revealed that the structure is quite different to the cartoons that were inferred from the original Voyager 2 measurements. Dr Masters commented: “Magnetic fields are tricky to understand, even when they are in simple systems. But Neptune is particularly badly behaved. Its odd properties challenge our basic ideas on how magnetospheres work.”

A snapshot of Neptune’s magnetic field from the movie. Credit: Lars Mejnertsen, Imperial College London. Click for a full size image“Modelling a whole planet is no easy task. But supercomputers now make it possible and the new simulations explain a lot of what Voyager saw all those years ago. For example, we can now see how the solar wind (the stream of electrically charged particles from the Sun) enters and circulates around Neptune’s magnetic field. The combination of the dramatic planetary rotation and this circulation pattern is why Voyager 2 found a ‘lopsided’ magnetosphere.”

Understanding Neptune better will also help astronomers understand planets outside the solar system. A large number of those found to date are Neptune-sized, so studying the gas giant should give an insight into conditions on those other distant worlds.

And while Neptune is one of the most exotic planets in the solar system, this work also finds applications closer to home, for models of the magnetic field of the Earth. The Earth’s field plays a key role in controlling space weather, which can harm technology in space and on the ground. Basic research into the magnetic fields of other planets will help scientists improve our ability to forecast space weather events such as geomagnetic storms.

Images, animation and captions

A movie showing how the configuration of the magnetic field changes with time during 1.5 days on Neptune. The colour corresponds to the strength of the magnetic field. Neptune itself is the sphere centred on the donut-shaped 'inner magnetosphere' (bottom left) and the magnetic field lines streaming away from the planet to the right correspond to the 'magnetotail'. Credit: Lars Mejnertsen, Imperial College London

Neptune as observed by Voyager 2 during its flyby in 1989. Credit: NASA/JPL

A snapshot of Neptune's magnetic field from the movie: Credit: Lars Mejnertsen/Imperial College London

The Royal Astronomical Society (RAS), founded in 1820, encourages and promotes the study of astronomy, solar-system science, geophysics and closely related branches of science. The RAS organises scientific meetings, publishes international research and review journals, recognizes outstanding achievements by the award of medals and prizes, maintains an extensive library, supports education through grants and outreach activities and represents UK astronomy nationally and internationally. Its more than 3800 members (Fellows), a third based overseas, include scientific researchers in universities, observatories and laboratories as well as historians of astronomy and others. Follow the RAS on Twitter

The Science and Technology Facilities Council (STFC) is keeping the UK at the forefront of international science and tackling some of the most significant challenges facing society such as meeting our future energy needs, monitoring and understanding climate change, and global security. The Council has a broad science portfolio and works with the academic and industrial communities to share its expertise in materials science, space and ground-based astronomy technologies, laser science, microelectronics, wafer scale manufacturing, particle and nuclear physics, alternative energy production, radio communications and radar. It enables UK researchers to access leading international science facilities for example in the area of astronomy, the European Southern Observatory. Follow STFC on Twitter

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